JPH06250068A - Lens barrel - Google Patents

Abstract

PURPOSE:To provide a lens barrel which can drive a focus lens at a high speed and accurately stop it by a simple constitution. CONSTITUTION:A hollow motor 3 is disposed coaxially with a lens barrel body 1 so that the focus lens 2 is moved in an optical axis direction by a focus driving cam 9 turned together with the rotor 3B of the motor 3. When the movement of the lens 2 is stopped, the rotor 3B is locked so that it cannot be rotated by engaging the lever 4A of a lock mechanism 4 with a gear 3C provided around the rotor 3B of the motor 3. Since the rotor 3B of the motor 3 is locked in such a way, the overrunning of the rotor 3B caused by the inertia thereof is prevented from occurring and the stopping accuracy of the rotor 3B is improved at a focusing time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lens barrel, and more particularly to a lens barrel capable of operating a focusing mechanism or the like by a hollow motor.

[0002]

2. Description of the Related Art Conventionally, when a focus lens is driven by a motor, a stepping motor is used or a DC motor is provided with a speed reducer to obtain a desired stopping accuracy. However, in the case of these motors, it is difficult to drive them at high speed, the cost is high, and further, the motor, the speed reducer, and the like project outside the lens barrel, which hinders downsizing.

On the other hand, a lens barrel (Japanese Patent Laid-Open No. 61-50916) in which a focus mechanism and an aperture mechanism are driven by two hollow motors, and a focus mechanism and a zoom mechanism are respectively driven by two hollow motors. A lens barrel that is driven (Japanese Patent Laid-Open No. 60-2063), and a lens barrel that is driven by a hollow motor to drive a focus mechanism and a diaphragm mechanism, respectively (Japanese Patent Laid-Open No. 61-22171).
No. 5 bulletin). The focus mechanism driven by these hollow motors is a system in which the focus lens is extended by multiple rotations of the hollow motor.

[0004]

However, even in the lens barrel using the hollow motor, it is not possible to satisfy both the high speed lens feed and the stopping accuracy, and the brushless motor is used for high speed. When the focus lens is directly driven, there is a problem that desired stop accuracy cannot be obtained because of overrun due to inertia.

The present invention has been made in view of such circumstances, and it is possible to drive the focus lens at a high speed with a simple structure and to stop the focus lens with high accuracy. Further, the focus mechanism and the zoom mechanism can be driven by one hollow motor. It is an object of the present invention to provide a lens barrel capable of operating two mechanisms such as.

[0006]

In order to achieve the above object, the present invention provides a hollow motor arranged coaxially with a lens barrel, a focus lens arranged movably in an optical axis direction, and A power transmission mechanism that transmits the rotational driving force of the rotor of the hollow motor to the focus lens, a locked portion that is provided around the rotor of the hollow motor and has irregularities of a predetermined pitch, and the locked portion. Has a locking member that engages with
A locking mechanism that locks the rotor in a non-rotatable manner by engaging the locking member with the locked portion.

Further, a hollow motor having an inner cylinder and an outer cylinder coaxial with the lens barrel, the inner cylinder and the outer cylinder being rotatably arranged with respect to the lens barrel, and movable in the optical axis direction. A first optical member and a second optical member other than the first optical member
Optical member, first and second power transmission mechanisms for transmitting respective driving forces from the inner cylinder and the outer cylinder of the hollow motor to the first and second optical members, and the inner cylinder of the hollow motor. And first and second locked portions, which are provided on the periphery of the outer cylinder and have irregularities of a predetermined pitch, and locking members that engage with the first and second locked portions, A first position that engages only the first locked portion, a second position that engages the first and second locked portions, and only the second locked portion. A lock mechanism that locks the inner cylinder and / or one or both of the inner cylinder and the inner cylinder in a non-rotatable manner by moving the locking member to any one of the third positions. I am trying.

[0008]

According to the present invention, the rotor cannot be rotated by engaging the locking member of the lock mechanism with the locked portion which is formed around the rotor of the hollow motor and has a predetermined pitch. I am trying to lock it. Since the rotor is locked in this way, it is possible to prevent overrun due to inertia of the rotor and improve the stopping accuracy of the rotor during focusing.

According to another aspect of the present invention, the inner cylinder and the outer cylinder of the hollow motor are rotatably arranged with respect to the lens barrel, and are provided around the inner cylinder and the outer cylinder of the hollow motor, respectively. By engaging the locking member of the lock mechanism with one or both of the first and second locked portions formed of the unevenness of the predetermined pitch, either or both of the inner cylinder and the outer cylinder. Is locked so that it cannot rotate. This allows the focus mechanism to be driven by one hollow motor,
Two mechanisms such as a zoom mechanism can be operated, and the stopping accuracy is improved as in the above.

[0010]

The preferred embodiments of the lens barrel according to the present invention will be described in detail below with reference to the accompanying drawings. FIG. 1 is a sectional view showing a first embodiment of the lens barrel according to the present invention. In the figure, 1 is a lens barrel, 2 is a focus lens, 3 is a hollow motor, and 4 is a lock mechanism.

Guide shafts 5 and 6 are provided inside the lens barrel 1. The guide shafts 5 and 6 guide a lens frame 2A holding a focus lens 2 movably in the optical axis direction. Has been done. A hollow motor 3 is arranged on the inner circumference of the lens barrel 1. This hollow motor 3
Is a brushless motor, a stator 3A having a print coil 7A and the like is fixed to the lens barrel 1, and a magnet 7B.
A rotor 3B having the above elements is rotatably disposed via a bearing 8.

A focus drive cam 9 having a linear lead groove 9A is fixed inside the rotor 3B of the hollow motor 3, and a pin 2B provided on the lens frame 2A is fixed in the lead groove 9A. Engaged. Therefore, when the rotor 3B of the hollow motor 3 rotates, the lens frame 2A
The (focus lens 2) moves in the optical axis direction, and thereby focus adjustment is performed.

The lock mechanism 4 is composed of a lever 4A rotatably supported by a support shaft and a plunger 4B for rotating the lever 4A. The lever 4A is formed with a locking claw 4C for fixing the rotor 3B of the hollow motor 3 in a non-rotatable manner. When the lever 4A is rotated counterclockwise in FIG. 1 by the plunger 4B, The locking claw 4C meshes with the gear 3C (see FIG. 2) formed on the rear end peripheral surface of the rotor 3B to fix the rotor 3B in a non-rotatable manner.

Now, in the state shown in FIG. 1, the hollow motor 3
The rotor 3B of is rotatable. Here, focus adjustment is performed by driving the hollow motor 3, and when focus is detected, the hollow motor 3 is stopped and the lock mechanism 4 is operated to forcibly stop the rotor 3B. As a result, overrun due to inertia of the rotor 3B can be prevented, and the rotor 3B can be stopped at the in-focus position with high accuracy.

FIG. 3 is a sectional view showing a second embodiment of the lens barrel according to the present invention. In the figure, 10 is a front lens barrel and 12 is a rear lens barrel. A front lens G1 is fixed to the front part of the front lens barrel 10, and a master lens G5 is fixed to the rear part of the rear lens barrel 12. Further, the guide shafts 14 and 1 are provided between the front lens barrel 10 and the rear lens barrel 12.
6 is disposed, and the lens frame 2 in which the variator lens G2 is held by these guide shafts 14 and 16
0, lens frame 2 holding the compensator lens G3
2 and the lens frame 2 holding the focus lens G4
4 are guided so as to be movable in the optical axis direction.

Further, a zoom cam ring 26 is rotatably disposed on the inner circumference of the front lens barrel 10, and cam grooves 26A and 26B of the zoom cam ring 26 are provided with pins provided on the lens frames 20 and 22, respectively. 20A and 22A are engaged. On the other hand, a hollow motor 30 is arranged on the outer periphery of the rear lens barrel 12. The hollow motor 30 includes an inner cylinder 32,
The inner cylinder 3 includes an outer cylinder 34 and bearings 36 and 38 that rotatably support the inner cylinder and the outer cylinder.
A coil (not shown) is disposed on either one of the outer cylinder 2 and the outer cylinder 34, and a magnet is disposed on the other.

The bearing 36 of the hollow motor 30 is fixed by the front flange 12A of the rear lens barrel 12, and the bearing 38 is fixed by the motor fixing plate 40 arranged at the rear of the rear lens barrel 12. . As a result, the inner cylinder 32 and the outer cylinder 34 of the hollow motor 30 can rotate independently of each other. A linear lead groove 32A is formed in the inner cylinder 32 of the hollow motor 30,
In the lead groove 32A, the pin 24A provided on the lens frame 24 is formed in the rear lens barrel 12 to form the elongated hole 1 in the optical axis direction.
It is engaged through 2B. Further, the outer cylinder 34 of the hollow motor 30 is formed with a protruding portion 34A extending from the outer cylinder 34, and the protruding portion 34A has a length on an arc formed on the flange portion 12A of the rear lens barrel 12. It engages with an engaging portion 26C formed at the rear end of the zoom cam ring 26 via the hole 12C.

Therefore, when the inner cylinder 32 of the hollow motor 30 rotates, the lens frame 24 (focus lens G4) moves in the optical axis direction, whereby focus adjustment is performed. When the outer cylinder 34 of the hollow motor 30 rotates, the outer cylinder 34
At the same time, the zoom cam ring 26 rotates to move the lens frames 20 and 22 (variator lens G2 and compensator lens G3) in a fixed relationship in the optical axis direction, thereby performing zooming.

Next, the lock mechanism 42 for selectively fixing one or both of the inner cylinder 32 and the outer cylinder 34 of the hollow motor 30 will be described. This lock mechanism 42
Is a locking member 42A arranged so as to be movable in a direction orthogonal to the optical axis, and the locking member 42A is arranged at three positions (P _1, P _2, P
₃ ) It is composed of three stable plungers 42B which are moved to any one of the positions.

The locking member 42A is provided with a locking claw 42C for fixing the inner cylinder 32 and the outer cylinder 34 of the hollow motor 30 so that they cannot rotate. Now, in the state shown in FIG.
The locking member 42A has moved to the position P ₁ , and this position P 1
_{In 1} , the locking claw 42C of the locking member 42A meshes with the gear 32B formed on the rear end peripheral surface of the inner cylinder 32 to fix the inner cylinder 32 non-rotatably.

When the hollow motor 30 is driven,
The outer cylinder 34 rotates, the driving force is transmitted to the zoom cam ring 26 via the protrusion 34A of the outer cylinder 34 and the engaging portion 26C of the zoom cam ring 26, and the cam groove 26 of the zoom cam ring 26 is further transmitted.
A, 26B and pins 20A, 22 of the lens frames 20, 22
The driving force is transmitted to the lens frames 20 and 22 via A.
As a result, the lens frames 20 and 22 (variator lens G2 and compensator lens G3) move in the optical axis direction in a fixed relationship so that the focal length changes in a focused state.

On the other hand, when the locking member 42A is moved to the position P ₃ by the tri-stable plunger 42B, the locking member 4
The locking claw 42C of 2A meshes with the gear 34B formed on the rear end peripheral surface of the outer cylinder 34 to fix the outer cylinder 34 in a non-rotatable manner. Here, when the hollow motor 30 is driven, the inner cylinder 32 rotates, the driving force is transmitted to the lens frame 24 via the lead groove 32A of the inner cylinder 32 and the pin 24A of the lens frame 24, and the lens frame 24 ( The focus lens G4) moves in the optical axis direction. This adjusts the focus.

To stop the focusing or zooming operation, the hollow motor 3 is stopped and the locking member 42A is moved to the position P ₂ by the tri-stable plunger 42B. As a result, the locking claw 42C of the locking member 42A has the gears 32B and 34 formed on the rear end peripheral surfaces of the inner cylinder 32 and the outer cylinder 34.
The inner cylinder 32 and the outer cylinder 34 are non-rotatably fixed by meshing with B. That is, by moving the locking member 42A to the position P ₂ by the tri-stable plunger 42B,
The rotation of the inner cylinder 32 or the outer cylinder 34 of the hollow motor 30 is forcibly stopped.

In the second embodiment, the two mechanisms, the focus mechanism and the zoom mechanism, are driven by one hollow motor, but the invention is not limited to this, and the focus mechanism, the zoom mechanism, the diaphragm mechanism, and the barrier. It is also possible to drive any two of the opening / closing mechanisms and the like.

[0025]

As described above, according to the lens barrel of the present invention, the locking member of the lock mechanism is fitted to the locked portion, which is provided around the rotor of the hollow motor and has irregularities of a predetermined pitch. Since the rotor is locked so that it cannot rotate, the overrun due to the inertia of the rotor can be prevented, and the accuracy of stopping the rotor at the time of focusing can be improved. Further, since the inner cylinder and the outer cylinder of the hollow motor are rotatably arranged with respect to the lens barrel and one or both of the inner cylinder and the outer cylinder are non-rotatably locked, one hollow motor With this, it is possible to operate two mechanisms such as a focus mechanism and a zoom mechanism, and at the same time, it is possible to improve the stop accuracy.

[Brief description of drawings]

FIG. 1 is a sectional view showing a first embodiment of a lens barrel according to the present invention.

FIG. 2 is a perspective view showing an example of an end face shape of a rotor of the hollow motor shown in FIG.

FIG. 3 is a sectional view showing a second embodiment of the lens barrel according to the present invention.

[Explanation of symbols]

 1 ... Lens barrel 2, G4 ... Focus lens 3, 30 ... Hollow motor 3A ... Stator 3B ... Rotor 3C, 32B, 34B ... Gear 4, 42 ... Lock mechanism 4A ... Lever 4B ... Plunger 5, 6, 14, 16 ... Guide shaft 9 ... Focus drive cam 10 ... Front lens barrel 12 ... Rear lens barrel 20, 22, 24 ... Lens frame 26 ... Zoom cam ring 32 ... Inner cylinder 34 ... Outer cylinder 36, 38 ... Bearing 40 ... Motor fixing plate 42A ... Locking member 42B ... 3 Stable plunger G2 ... Variator lens G3 ... Compensator lens

Claims (6)

[Claims] 1. A hollow motor arranged coaxially with a lens barrel, a focus lens arranged movably in the optical axis direction, and a rotational driving force of a rotor of the hollow motor transmitted to the focus lens. A power transmission mechanism, a locked portion that is formed around the rotor of the hollow motor and has a predetermined pitch, and a locking member that engages with the locked portion. And a locking mechanism for locking the rotor in a non-rotatable manner by engaging with the locked portion. 2. The lens barrel according to claim 1, wherein the hollow motor is a brushless motor. 3. The power transmission means comprises a focus drive cam that rotates together with the rotor of the hollow motor, and a pin that is provided on a lens frame that holds the focus lens and that engages with the focus drive cam. 1 or 2 lens barrel. 4. An inner cylinder and an outer cylinder coaxial with the lens barrel,
A hollow motor in which the inner cylinder and the outer cylinder are respectively rotatably arranged with respect to the lens barrel, a first optical member movably arranged in the optical axis direction, and a first optical member other than the first optical member. No. 2 optical member, and first and second optical members for transmitting the respective driving forces from the inner cylinder and the outer cylinder of the hollow motor to the first and second optical members, respectively.
Power transmission mechanism, first and second locked portions formed of irregularities of a predetermined pitch provided around the inner cylinder and the outer cylinder of the hollow motor, respectively, and the first and second locked portions. A first position for engaging only the first locked portion, a second position for engaging the first and second locked portions, And the locking member is moved to any one of a third position that engages only with the second locked portion, so that one or both of the inner cylinder and the outer cylinder cannot be rotated. A lens barrel having a locking mechanism for locking. 5. The hollow motor is a brushless motor, and a bearing between the inner cylinder and the outer cylinder is fixed to the lens barrel so that the inner cylinder and the outer cylinder are rotatable with respect to the lens barrel. The lens barrel according to claim 4, wherein the lens barrel is disposed in the lens barrel. 6. The lens barrel according to claim 4, wherein the first optical member is a focus lens, and the second optical member is a variator lens and a compensator lens.